Attosecond chronoscopy of electron scattering in dielectric nanoparticles

L. Seiffert; Q. Liu; S. Zherebtsov; A. Trabattoni; P. Rupp; M. C. Castrovilli; M. Galli; F. Submann; K. Wintersperger; J. Stierle; G. Sansone; L. Poletto; F. Frassetto; I. Halfpap; V. Mondes; C. Graf; E. Ruhl; F. Krausz; M. Nisoli; T. Fennel; F. Calegari; M. F. Kling

doi:10.1038/NPHYS4129

Attosecond chronoscopy of electron scattering in dielectric nanoparticles

L. Seiffert
, Q. Liu
, S. Zherebtsov
, A. Trabattoni
, P. Rupp
, M. C. Castrovilli
, M. Galli
, F. Submann
, K. Wintersperger
, J. Stierle
, G. Sansone
, L. Poletto
, F. Frassetto
, I. Halfpap
, V. Mondes
, C. Graf
, E. Ruhl
, F. Krausz
, M. Nisoli
, T. Fennel

F. Calegari, M. F. Kling

Research output: Contribution to journal › Article › peer-review

84 Scopus citations

Abstract

The scattering of electrons in dielectric materials is central to laser nanomachining1, light-driven electronics2 and radiation damage3-5. Here, we demonstrate real-time access to electron scatteringbyimplementingattosecondstreakingspectroscopy on dielectric nanoparticles: photoelectrons are generated inside the nanoparticles and both their transport through the material and photoemission are tracked on an attosecond timescale. We develop a theoretical framework for attosecond streaking spectroscopy in dielectrics and identify that the presence of the internal field inside the material cancels the influence of elastic scattering, enabling the selective characterization of the inelastic scattering time. The approach is demonstrated on silica nanoparticles, where an inelastic mean-free path is extracted for 20-30 eV. Our approach enables the characterization of inelastic scattering in various dielectric solids and liquids, including water, which can be studied in the form of droplets.

Original language	English
Pages (from-to)	766-770
Number of pages	5
Journal	Nature Physics
Volume	13
Issue number	8
DOIs	https://doi.org/10.1038/NPHYS4129
State	Published - 1 Aug 2017
Externally published	Yes

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Seiffert, L., Liu, Q., Zherebtsov, S., Trabattoni, A., Rupp, P., Castrovilli, M. C., Galli, M., Submann, F., Wintersperger, K., Stierle, J., Sansone, G., Poletto, L., Frassetto, F., Halfpap, I., Mondes, V., Graf, C., Ruhl, E., Krausz, F., Nisoli, M., ... Kling, M. F. (2017). Attosecond chronoscopy of electron scattering in dielectric nanoparticles. Nature Physics, 13(8), 766-770. https://doi.org/10.1038/NPHYS4129

@article{fcd0298a67e84ab1827955717aa65f5a,

title = "Attosecond chronoscopy of electron scattering in dielectric nanoparticles",

abstract = "The scattering of electrons in dielectric materials is central to laser nanomachining1, light-driven electronics2 and radiation damage3-5. Here, we demonstrate real-time access to electron scatteringbyimplementingattosecondstreakingspectroscopy on dielectric nanoparticles: photoelectrons are generated inside the nanoparticles and both their transport through the material and photoemission are tracked on an attosecond timescale. We develop a theoretical framework for attosecond streaking spectroscopy in dielectrics and identify that the presence of the internal field inside the material cancels the influence of elastic scattering, enabling the selective characterization of the inelastic scattering time. The approach is demonstrated on silica nanoparticles, where an inelastic mean-free path is extracted for 20-30 eV. Our approach enables the characterization of inelastic scattering in various dielectric solids and liquids, including water, which can be studied in the form of droplets.",

author = "L. Seiffert and Q. Liu and S. Zherebtsov and A. Trabattoni and P. Rupp and Castrovilli, \{M. C.\} and M. Galli and F. Submann and K. Wintersperger and J. Stierle and G. Sansone and L. Poletto and F. Frassetto and I. Halfpap and V. Mondes and C. Graf and E. Ruhl and F. Krausz and M. Nisoli and T. Fennel and F. Calegari and Kling, \{M. F.\}",

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Seiffert, L, Liu, Q, Zherebtsov, S, Trabattoni, A, Rupp, P, Castrovilli, MC, Galli, M, Submann, F, Wintersperger, K, Stierle, J, Sansone, G, Poletto, L, Frassetto, F, Halfpap, I, Mondes, V, Graf, C, Ruhl, E, Krausz, F, Nisoli, M, Fennel, T, Calegari, F & Kling, MF 2017, 'Attosecond chronoscopy of electron scattering in dielectric nanoparticles', Nature Physics, vol. 13, no. 8, pp. 766-770. https://doi.org/10.1038/NPHYS4129

TY - JOUR

T1 - Attosecond chronoscopy of electron scattering in dielectric nanoparticles

AU - Seiffert, L.

AU - Liu, Q.

AU - Zherebtsov, S.

AU - Trabattoni, A.

AU - Rupp, P.

AU - Castrovilli, M. C.

AU - Galli, M.

AU - Submann, F.

AU - Wintersperger, K.

AU - Stierle, J.

AU - Sansone, G.

AU - Poletto, L.

AU - Frassetto, F.

AU - Halfpap, I.

AU - Mondes, V.

AU - Graf, C.

AU - Ruhl, E.

AU - Krausz, F.

AU - Nisoli, M.

AU - Fennel, T.

AU - Calegari, F.

AU - Kling, M. F.

PY - 2017/8/1

Y1 - 2017/8/1

N2 - The scattering of electrons in dielectric materials is central to laser nanomachining1, light-driven electronics2 and radiation damage3-5. Here, we demonstrate real-time access to electron scatteringbyimplementingattosecondstreakingspectroscopy on dielectric nanoparticles: photoelectrons are generated inside the nanoparticles and both their transport through the material and photoemission are tracked on an attosecond timescale. We develop a theoretical framework for attosecond streaking spectroscopy in dielectrics and identify that the presence of the internal field inside the material cancels the influence of elastic scattering, enabling the selective characterization of the inelastic scattering time. The approach is demonstrated on silica nanoparticles, where an inelastic mean-free path is extracted for 20-30 eV. Our approach enables the characterization of inelastic scattering in various dielectric solids and liquids, including water, which can be studied in the form of droplets.

AB - The scattering of electrons in dielectric materials is central to laser nanomachining1, light-driven electronics2 and radiation damage3-5. Here, we demonstrate real-time access to electron scatteringbyimplementingattosecondstreakingspectroscopy on dielectric nanoparticles: photoelectrons are generated inside the nanoparticles and both their transport through the material and photoemission are tracked on an attosecond timescale. We develop a theoretical framework for attosecond streaking spectroscopy in dielectrics and identify that the presence of the internal field inside the material cancels the influence of elastic scattering, enabling the selective characterization of the inelastic scattering time. The approach is demonstrated on silica nanoparticles, where an inelastic mean-free path is extracted for 20-30 eV. Our approach enables the characterization of inelastic scattering in various dielectric solids and liquids, including water, which can be studied in the form of droplets.

UR - https://www.scopus.com/pages/publications/85026818064

U2 - 10.1038/NPHYS4129

DO - 10.1038/NPHYS4129

M3 - 文章

AN - SCOPUS:85026818064

SN - 1745-2473

VL - 13

SP - 766

EP - 770

JO - Nature Physics

JF - Nature Physics

IS - 8

ER -

Attosecond chronoscopy of electron scattering in dielectric nanoparticles

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